DE19935146A1 - Contactless communication system - Google Patents

Abstract

In a non-contact communication system, the interrogator transmits a weak radio wave from its tuning circuit when an interrogator tries to recognize that a responder is in a communicable area with it. The responder receives the radio wave and gains electrical power by rectifying it, but since the electrical power thus obtained is insufficient, the responder is turned on and off at regular intervals. This causes a change in the impedance with which the tuning circuit is loaded. The interrogator detects this change in impedance, which occurs at regular intervals, that the responder is present in the communicable area with it. Only then will the interrogator transmit a radio wave that is strong enough to allow the responder to gain enough electrical power.

Description

BACKGROUND OF THE INVENTION Field of invention

The invention relates to a non-contact commu nication system in which one of an interrogator over carried radio wave is received by a responder and the responder receiving electrical power from the A radio wave is generated and additional data from one of the received radio wave carried modulated signal restored to in response to the received data Transfer response data back to the interrogator.

Description of the prior art

As a non-contact communication system (non-contact communication system) are traditionally radio-free quenz tags (RF tags, radio-frequency tags) and ID cards known the electrical power from a radio wave he hold that is transmitted by an antenna to the in to transfer data stored to them themselves. Such sy For example, systems are used with the lifts in ski areas, with ticket inspection equipment of train stations and the general sorting of luggage.  

Such RF tags and ID cards are considered a touch free card trained which is a non-volatile memory and a transmitter / receiver unit (transmitter / receiver unit) that are included, but they don't have any Power or energy source like a battery. Such a Non-contact card works with the electrical Lei power generated by a radio wave (radio frequency modulated signal) that it receives. Furthermore such a non-contact card exchanges data with yours Communication partners through a radio wave and thus offers the advantage of non-contact data communication cation.

With such a non-contact communication system becomes a non-contact card, for example, as a respon who uses. The responder receives one from an inter rogator transmitted radio wave and gains electrical lei from the received radio wave. Therefore the In terrogator usually a radio wave all the time for communication, which is sufficient strong electrical power contributes to the responder allow to work from a relatively distant place work. That is why this non-contact communica tion system, even if there is no responder within the Be realm in which communication is possible is the interrogator for the transmission of the radio wave continue communication and this is of course one Waste of electrical power.

In addition, it is with this non-contact communication cation system initially undesirable, the interrogator to have a radio wave transmitted all the time, the one has sufficient electrical power to carry it Allow responders to work as this is an interfe with the operation of other electrical equipment things or have an adverse effect on human Body can exercise.  

SUMMARY OF THE INVENTION

An object of the invention is a non-contact To create communication system in which an interrogator less electrical power to transmit a radio wave consumed.

Another object of the invention is a touch to create a free communication system in which those of ei Radio wave transmitted to an interrogator if not communicates with a responder, no interference with the Operation of other electrical equipment is still causing has adverse effects on human bodies.

To invent the above tasks according to an invented Achieving the aspect of the invention becomes a non-contact Communication system provided, with a first com communication unit for emitting a radio wave for the Communication and a second communication unit Communication with the first communication unit, wherein the first communication unit is a radio wave for the De tection produces weaker than the radio wave for the Communication is so that the first communication unit by detecting a predetermined change in the radio wave for detection recognizes that the second communication unity within a communicable area of the he Most communication unit is present, and then the Transmission of the radio wave for communication begins.

Corresponds to this configuration, if the second communication unit not within the commun range of the first communication unit available that is and therefore none of these are one communication performs, the first communication unit a Ra diowave which is weaker than the radio wave which it for ordinary communication. Thus we  less electrical power consumed and accordingly higher energy efficiency than in a known system achieved, which requires that a strong radio wave is transmitted for communication.

In addition, if the second communication unit is not in the communicable area of the first communication unity exists and so none of these commun performs the communication process, transmits the first communication onsunit a radio wave that is weaker than the radio wave le is that they use for ordinary communication wearing. As long as there is no communication process occurs, less possibility of interference with others electrical equipment or adverse effects human body.

In addition, touch transmits in the invention the first communication alternate the radio wave for communication or the radio wave for detection by a single Transmission means used by these two Radio waves is shared. Using one Transmission means for transmitting the radio wave for the Communication and radio wave for detection the need for separate means of transmission for the transmission of the radio wave for communication and to be provided for the radio wave for detection. So can the first communication unit used here simply there can be obtained by little modification in one known configuration is made and thus No large-scale reconfiguration needed.

In addition, the inventive contact occurs free communication system the repeated activation and Deactivation of the second communication unit in regular intervals because the radio wave for detection, which is transmitted by the first communication unit,  is so weak that it equals critical strength, between activation and deactivation of the second communication unit disconnects when the second com communication unit within the communicable area the first communication unit is present. The touch communication system is equipped with a detector tel for detecting the change in the amplitude of the first communication unit transmitted radio waves designed from such repeated activations and Deactivations of the second communication unit result a verification tool to check whether the second communication unit within the communicable Area of the first communication unit is present or not, based on the output of the detector means, and a control means for controlling the first communication tion unit for transmitting the radio wave for communication nication based on the output of the inspection material.

According to this configuration, the radio wave is for the detection made by the first communication unit is witnessed when the second communication unit outside of the communicable area with the first communicati unit is so weak with respect to the radio wave for the communication to electrical energy according to the to generate critical strength between the activation and deactivating the second communication unit, and thus the second communication unit is repeated activated and deactivated at regular intervals. This causes variation that occurs at regular intervals the impedance occurs with which the tuning circuit of the he most communication unit is loaded. The first commun cation unit recognizes by detecting this variation, that occurs at regular intervals, the presence the second communication unit. Beyond that needed the second communication unit has no circuit, except ever ner who carries out the communication so that the first com communication unit the presence of the second communicati  unit recognizes, and thus the second communicati ons unit with the same configuration as in the known System in the non-contact communication according to the invention tion system can be used.

In addition, in the inventive contact free communication system is the second communication unit a signal generating means for generating an Ant word signal when the second communication unit Ra diowave detected for detection to the first communica unit to recognize that the second Communication unit within the communicable Be realm of the first communication unit is present.

The second communication unit has a circuit that can work with the inadequate electrical power, which is received from a radio wave, which from which he Most communication unit is generated, the weaker than being the radio wave for communication. Additional Lich the circuit keeps the weaker radio wave modulated at a fixed frequency over time. So if he most communication unit is made to recognize that the second communication unit within the commu nizeable area with it, the first Communication unit can be supplied with a signal that does not depend on the characteristics of the circuit that to achieve within the second communication unit communication is provided.

According to a further aspect according to the invention, in a non-contact communication system with a first communication unit for transmitting a radio wave le for communication and a second communication unit for communication with the first communicati ons unit is equipped, a mechanical or opti shear sensor within the first communication unit provided so that the first communication unit the  Transmission of the radio wave for communication begins when the first communication unit recognizes that the second communication unit within the communicable Area of the first communication unit is present. This allows the electrical power to be reduced which is consumed when there is no communication between the second communication units occurs, and switches the possibility of serious interference with other electri equipment or adverse effects on human Body out.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other objects and features of the invention will be from the following description in connection with the be preferred embodiments with reference to the accompanying Drawings clearly showing:

Fig. 1 is a block diagram of the internal arrangement of the Inter rogators, as applied in a first and a second embodiment of the invention;

Fig. 2 is a block diagram of the internal arrangement of the respon used in the first and a third embodiment of the invention;

Fig. 3 is a diagram of the waveform of the radio waves for responder detection and for the communication;

FIGS. 4A to 4D are diagrams of equivalent circuits of the antenna circuit at tion system in a non-contact communica;

Fig. 5 is a block diagram of the internal arrangement of the respon used in the second embodiment of the inven tion;

Fig. 6 is a block diagram of the internal arrangement of the inter rogator used in the third embodiment of the invention; and

Fig. 7 is a block diagram of the internal arrangement of the Inter rogators with two tuning circuits, which is applied in the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENT

A first embodiment of the invention will be described with reference to FIGS. 1 to 3. Fig. 1 is a block diagram showing the internal arrangement of the interrogator 1 used in the first embodiment.

The interrogator 1 has a controller 8 , a carrier signal supply circuit 2 for supplying a carrier signal having a predetermined frequency f, a modulation circuit 3 for modulating the carrier signal in accordance with data supplied from the controller 8 , an output adjustment device 4 for control the output power for the carrier signal, a tuning circuit 5 with functions for transmitting and receiving a radio wave S and a first signal detector 6 and a second signal detector 7 for detecting a response signal from a responder 10 , which will be described later. The controller 8 consists of a microcomputer or the like and controls the carrier signal supply circuit 2 , the modulation circuit 3 , the output setting device 4 , the first signal detection circuit 6 and the second signal detection circuit 7 .

Fig. 2 is a block diagram showing the internal arrangement of a responder 10 with an IC circuit 11 . The Re sponder 10 has a tuning circuit 12 , which tunes to the carrier signal with the frequency f, which is transmitted by the interrogator 1 , and also has a rectifier circuit 13 , a switch 14 , a demodulation circuit 15 within the IC circuit 11 , a regulator 16 and a data processing circuit 17 . The tuning circuit 12 be consists of an induction element L and a capacitor C.

In a non-contact communication system that uses an interrogator 1 and a responder 10 , which are configured as described above, if the re sponder 10 is not present within the communicable range of the interrogator 1 , the controller 8 adjusts the output power setting device 4 that a radio wave set by the output setting device 4 is 10 dB weaker than a radio wave in which ordinary communication (hereinafter referred to as a radio wave for communication) is transmitted from the tuning circuit 5 . In the following descriptions of the invention, this radio wave that is transmitted to enable detection of whether or not the responder 10 is included within the communicable range is referred to as a radio wave for the responder detection.

The power of the radio wave for responder detection is adjusted to be sufficiently weak so as not to affect other electrical equipment and to be equal to the critical strength that separates the strength that generates sufficient electrical power to the responder 10 activate within a given range and the strength that does not. The critical strength differs according to the characteristics of the responder. The radio wave for the responder detection, for which the controller 8 does not supply a modulation signal to the modulation circuit 3 , has a signal course as shown with (a) in FIG. 3.

Although no radio wave modulation signal for the Re sponder detection is added as previously for this embodiment is described, it is also possible as a radio wave for responder detection, a radio wave to use, which has an added modulation signal.  

When the radio wave is transmitted for responder detection, the controller 8 keeps the carrier signal supply circuit 2 , the output setting device 4 and the second signal detector 7 active, whereas it keeps the first signal detector 6 inactive. In this state, the controller 8 does not supply a modulation signal to the modulation circuit 3 . This state is then referred to as the detection mode. On the other hand, the state in which the non-contact communication with the responder 10 takes place is referred to as the communication mode.

In FIG. 4A, the tuning circuit 5 of the interrogator 1 and the IC circuit 11 of the responder 10, together with the space between them, can be regarded as forming an antenna circuit 100 . Therefore, if it is assumed that the impedance with which the tuning circuit 5 of the interrogator 1 is loaded is Z ₀ , as shown in FIG. 4B, when the responder 10 is deactivated, it is Z ₁ , as in FIG Fig. 4C is shown when the re sponder 10 is active and the switch 14 is open, and is equal to Z ₂ , as shown in Fig. 4D when the re sponder 10 is active and the switch 14 is closed, then meet these values of impedance have the relationship Z ₀ <Z ₁ <Z ₂ . In Fig. 4A, the number 11 represents the internal circuit of the IC circuit 11.

When the tuning circuit adjusts derdetektion 12, the radio wave for the Respon, oriented in the responder 10, the rectifying circuit 13, the receiving radio wave is equal, and thereby generates the electrical power which is supplied in the C-circuit. With this electrical power, the responder 10 tries to work. At this time, since the switch 14 in the responder 10 is open, the impedance with which the tuning circuit 5 is loaded in the interrogator 1 changes from Z ₀ to Z ₁ . Such a change in impedance causes the consumption of electrical power within the responder 10 and thereby reduces the amplitude and thus the power of the radio wave for the responder detection.

The output power of the radio wave for the responder detection is controlled so that the electrical power generated is insufficient for the operation of the responder 10 within a predetermined range. Therefore, if this radio wave shows a change in amplitude as described above, it will generate less electrical power than is necessary to make the responder 10 work, and thus the responder 10 stops operating. This causes the above-mentioned impedance to return to Z ₀ , which enables the radio wave for the response detection to recover the original amplitude. As a result, responder 10 begins to work again.

In this way, the responder 10 is repeatedly activated and deactivated and therefore the radio wave for the re sponder detection now has a signal curve of a signal that is modulated with a predetermined frequency f1, as shown with (b) in FIG. 3. In addition, as a result of the repeated activation and deactivation of the responder as described above, even if the interrogator 1 transmits a data-carrying radio wave, the data processing circuit 17 cannot process the data appropriately, and therefore the data processing circuit 17 never controls the data Switch 14 . Dement speaking remains when the responder 10 is active, the switch 14 is opened and thus the above-mentioned impedance is equal to Z ₁ .

The modulated signal as described above, which is output from the tuning circuit 5 of the interrogator 1 , is detected by the second signal detector 7 by means of a resonance circuit which is tuned to the frequency f1 of the signal, and the detection output is fed to the controller 8 .

Upon detection of this signal with the frequency f1, the interrogator 1 recognizes through the operation of the controller 8 that the responder 10 is present within a communicable range. The controller 8 now controls the output setting device 4 to increase the output of the transmitted signal, deactivates the second signal detector 7 and activates the first signal detector 6 . In addition, the controller 8 simultaneously starts supplying a modulation signal to the modulation circuit 3 . Switching from the detection mode to the communication mode is achieved with.

At this time, the carrier signal supplied from the carrier signal supply circuit 2 is modulated in the modulation circuit 3 in accordance with the data Q supplied from the controller 8 , and then a radio wave for communication which has been amplified by the output power setting device 4 so that it has sufficient electrical power to make the response of the 10 work from the tuning circuit 5 . This radio wave for communication is a radio frequency signal in which modulated waves that are modulated in accordance with the data Q and non-modulated waves that are not modulated in accordance with the data Q alternately in the time periods T1 and T2 each occur as shown at (c) in FIG. 3.

When the tuner circuit 12 of the responder 10 receives the radio wave for communication, the radio wave for communication is rectified by the rectifier circuit 13 to generate electric power, and with this electric power, the responder 10 starts working. At this time, the data Q of the radio wave for communication occur by demodulating the modulated wave, the margin in time T1, is processed by use of the demodulation circuit 15 of the Da tenverarbeitungsschaltung 17 and the movement of such data processing circuit 17 outputs the response data A from. The response data A consist of a sequence of pulses by means of which the switch 14 switches on and off. Turning the switch 14 on and off in this way causes the impedance with which the tuning circuit 5 of the interrogator 1 is loaded to be changed in such a way that it becomes equal to Z ₁ when the switch 14 is off and that it becomes equal to Z ₂ when the switch 14 is on.

Since the above-mentioned impedance with which the tuning circuit 5 is loaded changes, the non-modulated waves in the time period T2 are amplitude-modulated in accordance with the response data A as shown at (d) in FIG. 3. This signal is detected by the first signal detector 6 and the detected signal is fed to the controller 8 .

Upon termination of communication between the interrogator 1 and the responder 10 , as described above, the switch from the communication mode back to the detection mode is achieved. At this time, the controller 8 stops supplying the modulation signal to the modulation circuit 3 and adjusts the setting of the output setting device 4 to reduce the output of the output setting device 4 . In addition, the second signal detector 7 is activated and the first signal detector 6 is deactivated.

In the embodiment discussed here, the interrogator 1 uses only one tuning circuit 5 for transmitting the radio wave for the responder detection and that of the radio wave for the communication, and it uses one of two separate signal detectors 6 and 7 , depending on whether it is in the detection or the communication mode works. However, it is also possible, as shown in Fig. 7, the interrogator 13 with a tuning circuit 5 a for the transmission of a radio wave for the responder detection, a tuning circuit 5 b for the transmission of a radio wave for communication and an output selection device 20 between them Tuning circuits 5 a and 5 b and the output adjustment device 4 , the tuning circuits 5 a and 5 b, each being connected to the signal detectors 6 and 7 .

When the interrogator 1 B as a means for detecting the applicatio ence of the responder 10 within a communicable range, and as a means for achieving the communication used with the responder 10, the same means can be used which have been described above. However, when switching from the detection mode to the communication mode and vice versa, the controller 8 must not only switch the setting of the output power for the output power setting device 4 , but also the output selection device 20 for switching the determination of the output between the tuning circuits 5 a and 5 b. More specifically, the controller 8 switches the output selection device 20 in such a way that in the detection mode a weak radio wave S1 is transmitted by the tuning circuit 5 a and in the communication mode an amplified radio wave S2 is transmitted by the tuning circuit 5 b.

If a responder 10 A ( FIG. 5) is used with a specialized circuit that works in the radio wave for the responder detection, as will be described later in connection with the second embodiment, the impedance Z ₁ , which at ( b) shown in FIG. 3 differ from the impedance Z ₁ shown at (d) in FIG. 3.

A second embodiment of the invention will be described with reference to FIGS. 1 and 5. The interrogator used in the second embodiment has the same configuration as the interrogator 1 used in the first embodiment and is shown in FIG. 1.

Fig. 5 is a block diagram showing the internal configuration of the responder used in this embodiment, 10 A. This responder 10 A, similar to the responder 10 used in the first embodiment, has a tuning circuit 12 which is tuned to the carrier signal with the frequency f which is transmitted by the interrogator 1 and has an integrated IC circuit 11 Rectifier circuit 13 , a switch 14 , a demodulation circuit 15 and a regulator 16 . In addition, the Re sponder 10 A in the IC circuit 11 also has a first data processing circuit 17 a, which can operate at comparatively low power, a second data processing circuit 17 b to perform signal processing in the communication mode, a switch 18 and a switch control 19 for controlling the switch 18 .

In a non-contact communication system using an interrogator 1 and a responder 10 A, which is configured as described above, if the responder 10 A is not in the communicable area with the interrogator 1 , the interrogator 1 in the detection mode corresponds to that first embodiment and therefore the output power setting device 4 controls the output power of the radio wave for communication so that a radio wave 10 dB weaker than the radio wave for communication as a radio wave for responder detection is transmitted from the tuning circuit 5 .

Also in this embodiment, as in the first embodiment form, no modulation signal of the radio wave for added responder detection. Beyond that it is  also possible for the radio wave for responder detection to use a radio wave that has an added modula tion signal.

If the tuning circuit 12 of the responder 10 A receives this radio wave for the responder detection, the radio wave for the responder detection is rectified by the rectifier circuit 13 for generating the electrical power and with the electrical power, the responder 10 A starts to work. At this time, the switch 18 is in the contact position "a" and therefore the electrical power generated by the rectifier circuit 13 is supplied to the first data processing circuit 17 a, which is thereby activated. On the other hand, no electrical power is supplied to the second data processing circuit 17 b, which thus remains inactive.

When the first data processing circuit 17a starts operating, it outputs data consisting of a sequence of pulses with a predetermined frequency f2. In synchronization with this data, the switch 14 is repeatedly switched on and off in order to change the impedance of the tuning circuit 12 .

By changing the impedance of the tuning circuit 12 , as described above, the radio wave for the Re sponder detection is amplitude modulated with the frequency f2. The resulting modulated signal causes the impedance to change across the tuning circuit 5 of the interrogator 1 . This change is detected by the second signal detector 7 with a resonance circuit which is tuned to the frequency f2 of this signal, and the detection output is fed to the controller 8 .

Upon detection of the above-mentioned signal, the inter rogator 1 recognizes through the operation of the controller 8 that the re sponder 10 a is present within a communicable area. The controller 8 now controls the output setting device 4 to increase the output of the transmitted signal, deactivates the second signal detector 7 and activates the first signal detector 6 . Thus, switching from the detection mode to the communication mode is achieved. In the communication mode, the interrogator 1 works in the same manner as in the first embodiment for transmitting the radio wave for communication, while a modulation signal is supplied to the modulation circuit 3 . If the tuning circuit 12 of the responder 10 a is tuned to the radio wave for communication, a sudden increase in the electrical power generated by the radio wave is detected by the switching controller 19 , which then switches the switch 18 to the contact position "b "switches.

When the responder 10 A is ready for communication with the inter rogator 1 in this way, the communication is performed as shown in the first embodiment. At the end of the communication or when the electrical power supplied to the responder 10 A becomes weaker, the interrogator 1 returns to the detection mode and thus the switch controller 19 switches the switch 18 back to the contact position "a". It should be noted that the second data processing circuit 17 b in this embodiment corresponds to the data processing circuit 17 of the first embodiment, and thus the former operates in the same way as the latter. In addition, in this embodiment as well as in the first embodiment, it is possible to use an interrogator 1 a with separate tuning circuits 5 a and 5 b for the detection and communication modes, as shown in FIG. 7.

Next, a third embodiment of the present invention will be described with reference to FIGS. 2 and 6. The responder used in this embodiment has the same configuration as the responder shown in Fig. 2 and used in the first embodiment.

Fig. 6 is a block diagram showing the internal configuration of the interrogator 1 B, which is used in this embodiment. The interrogator 1 B has a controller 8 B, a carrier signal supply circuit 2 for supplying a carrier signal having a predetermined frequency f, a modulation circuit 3 for modulating the carrier signal in accordance with data supplied by the controller 8 B, a tuning circuit 5 with functions for transmission and reception of a radio wave and a second signal detector 7 for detecting a response signal from the responder 10 , and a sensor unit 9 with an optical sensor or the like for detecting the presence of the re sponder 10 within a communicable area with the interrogator 1 B. The controller 8 B consists of a microcomputer or the like and controls the carrier signal supply circuit 2 , the modulation circuit 3 and the second signal detection circuit 7 .

If the responder 10 of the interrogator is placed 1 B in the vicinity of the sensor unit 9, which is configured as described above, 10 detects the optical sensor provided in the sensor unit 9, optical approximation of the responder to the interrogator 1 B. The detection output of the controller 8 is fed B. As a result, the control 8 B activates the entire interrogator 1 B, so that the interrogator 1 B communicates with the responder 10 .

Then, the interrogator 1 B operates in the same way as it has done in the communication mode in the first and second embodiment, except that in the ser embodiment, no radio wave for the Responderde tektion is transmitted in the detection mode. Therefore, the descriptions of the overlapping details are not repeated here.

In this embodiment, an optical means, namely an optical sensor, is used as a switch in order to let the interrogator 1 B start communication. It is also possible, however, instead a mechanical means to be used, for example, causes a Berüh tion on a touch panel the interrogator 1 B to start communicating.

Claims (9)

1. Non-contact communication system with:
a first communication unit for broadcasting a radio wave for communication; and
a second communication unit for communication with the first communication unit,
wherein the first communication unit generates a radio wave for detection that is weaker than the radio wave for communication, so that the first communication unit recognizes by detecting a predetermined change in the radio wave for detection that the second communication unit is within a communicable range the first communication unit is present and then the transmission of the radio wave for communication begins. 2. The non-contact communication system according to claim 1, wherein the first communication unit comprises:
a detector means for detecting the variation in amplitude in the radio wave transmitted from the first communication unit, which results from the repeated activation and deactivation of the second communication unit at regular intervals that occur since the radio wave for the detection that is emitted by the first communication unit, is so weak that it is equal to the critical strength, which distinguishes between activation and deactivation of the second communication unit, if the second communication unit is present within the communicable area of the first communication unit;
checking means for checking whether or not the second communication unit is present within the communicable area of the first communication unit based on the output of the detector means; and
a control means for controlling the first communication unit for transmitting the radio wave for communication based on the output of the checking means. 3. Non-contact communication system according to claim 1, in which the second communication unit is a signaler contains generating means for generating a response signal, when the second communication unit uses the radio wave for the detection is detected so as to be the first communication let it be recognized that the second communication is unit within the communicable area of the first Communication unit is present. 4. Non-contact communication system according to claim 1, where the first communication unit alternate the Radio wave for communication or radio wave for the detection transmits by a single transmission medium is used, the ge of these two radio waves is shared. 5. The non-contact communication system according to claim 4, wherein the first communication unit has:
a detector means for detecting the variation in amplitude in the radio wave transmitted from the first communication unit, which is based on the repeated activation and deactivation of the second communication unit at regular intervals that occur because the radio wave is used for detection by the first communication unit is transmitted is so weak that it is equal to the critical strength that separates the activation and deactivation of the second communication unit if the second communication unit is present within the communicable area of the first communication unit;
checking means for checking whether or not the second communication unit is present within the communicable area of the first communication unit based on the output of the detector means; and
a control means for controlling the first communication unit for transmitting the radio wave for communication based on the output of the checking means. 6. Non-contact communication system according to claim 4, in which the second communication unit is a signaler has generating means for generating a response signal if the second communication unit is the radio wave for the De tection detected, so the first communication unit to let know that the second communication unit in within the communicable area of the first communica tion unit is available. 7. Non-contact communication system according to claim 6, in which the radio wave is designed for detection is to change by changing an impedance within the second communication unit, based on the responsesi signal generated by the signal generating means to change. 8. Non-contact communication system with a first Communication unit for sending a radio wave for the communication and a second communication unit for communication with the first communication unit, being a mechanical or optical sensor inside the first communication unit is provided so that the first communication unit is the transmission of the radio wave for communication starts when the first commu nikationseinheit recognizes that the second communication unit within the communicable area of the first Communication unit is present.   9. Non-contact communication system with:
a first communication unit for transmitting a radio wave for communication; and
a second communication unit which receives the radio wave in order to obtain electrical energy from it and thereby to communicate with the first communication unit,
wherein the first communication unit generates a radio wave for detection that is weaker than the radio wave for communication, so that the first communication unit recognizes by detecting a predetermined change in the radio wave for detection that the second communication unit is within a communicable range of the first communication unit is present and then begins to transmit the radio wave for communication.